Dimeric Bis-Benzimidazole-Pyrroles DB2Py(n) - AT-Site-Specific Ligands: Synthesis, Physicochemical Analysis, and Biological Activity.

IF 2 4区 生物学 Q4 CELL BIOLOGY
O Y Susova, S S Karshieva, A A Kostyukov, N I Moiseeva, E A Zaytseva, K V Kalabina, E Zusinaite, K Gildemann, N M Smirnov, A F Arutyunyan, A L Zhuze
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引用次数: 0

Abstract

Its broad spectrum of biological activity makes benzimidazole a fundamental pharmacophore in pharmaceutics. The paper describes newly synthesized AT-specific fluorescent bis-benzimidazole molecules DB2Py(n) that contain a pyrrolcarboxamide fragment of the antibiotic drug netropsin. Physico-chemical methods using absorption, fluorescence, and circular dichroism spectra have shown the ability of bis-benzimidazole- pyrroles to form complexes with DNA. The new DB2Py(n) series have turned out to be more toxic to human tumor lines and less vulnerable to non-tumor cell lines. Bis-benzimidazole-pyrroles penetrated the cell nucleus, affected the cell-cycle synthesis (S) phase, and inhibited eukaryotic topoisomerase I in a cellfree model at low concentrations. A real-time tumor cell proliferation test confirmed the molecule's enhanced toxic properties upon dimerization. Preliminary cytotoxicity data for the bis-benzimidazole-pyrroles tested in a cell model with a MDR phenotype showed that monomeric compounds can overcome MDR, while dimerization weakens this ability to its intermediate values as compared to doxorubicin. In this respect, the newly synthesized cytotoxic structures seem promising for further, in-depth study of their properties and action mechanism in relation to human tumor cells, as well as for designing new AT-specific ligands.

二聚双苯并咪唑-吡咯 DB2Py(n) - AT-位点特异性配体:合成、理化分析和生物活性。
苯并咪唑具有广泛的生物活性,因此是制药学中的基本药源。本文介绍了新合成的 AT 特异性荧光双苯并咪唑分子 DB2Py(n),该分子含有抗生素药物奈托普生的吡咯甲酰胺片段。利用吸收、荧光和圆二色光谱的物理化学方法显示,双苯并咪唑-吡咯能与 DNA 形成复合物。结果表明,新的 DB2Py(n) 系列对人类肿瘤细胞株的毒性更强,而对非肿瘤细胞株的毒性较弱。在无细胞模型中,低浓度的双苯并咪唑吡咯可渗透细胞核,影响细胞周期合成(S)期,并抑制真核拓扑异构酶 I。一项实时肿瘤细胞增殖测试证实了二聚化后分子毒性增强的特性。在具有 MDR 表型的细胞模型中测试的双苯并咪唑吡咯化合物的初步细胞毒性数据显示,单体化合物可以克服 MDR,而二聚化则将这种能力削弱到与多柔比星相比的中间值。在这方面,新合成的细胞毒性结构似乎很有希望进一步深入研究它们与人类肿瘤细胞有关的特性和作用机制,以及设计新的 AT 特异性配体。
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来源期刊
Acta Naturae
Acta Naturae 农林科学-林学
CiteScore
3.50
自引率
5.00%
发文量
0
审稿时长
>12 weeks
期刊介绍: Acta Naturae is an international journal on life sciences based in Moscow, Russia. Our goal is to present scientific work and discovery in molecular biology, biochemistry, biomedical disciplines and biotechnology. These fields represent the most important priorities for the research and engineering development both in Russia and worldwide. Acta Naturae is also a periodical for those who are curious in various aspects of biotechnological business, innovations in pharmaceutical areas, intellectual property protection and social consequences of scientific progress. The journal publishes analytical industrial surveys focused on the development of different spheres of modern life science and technology. Being a radically new and totally unique journal in Russia, Acta Naturae is useful to both representatives of fundamental research and experts in applied sciences.
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